A vapor compression system (200; 400; 600; 700; 800; 900; 1000) comprises a plurality of valves (260, 262, 264; 260) controllable to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: a compressor (22); a first heat exchanger (30); a first nozzle (228; 624); and a separator (48), and then branching into: a first branch returning to the compressor; and a second branch passing through an expansion device (70) and a second heat exchanger (64) to the rejoin the flowpath between the first heat exchanger and the separator. The second mode flowpath is sequentially through: the compressor; the second heat exchanger; a second nozzle (248; 625); and the separator, and then branching into: a first branch returning to the compressor; and a second branch passing through the expansion device and first heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator.
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9. A vapor compression system comprising:
a compressor;
a first heat exchanger;
a second heat exchanger;
a separator having:
an inlet;
a liquid outlet; and
a vapor outlet;
an expansion device; and
an ejector comprising:
a first inlet;
a second inlet;
a first outlet;
a second outlet;
a first flowpath from the first inlet to the first outlet;
a second flowpath from the second inlet to the second outlet;
a first nozzle along the first flowpath;
a first mixer and a first diffuser along the first flowpath;
a second nozzle along the second flowpath; and
a second mixer and a second diffuser along the second flowpath, wherein:
the first flowpath and second flowpath merge downstream of the first nozzle and second nozzle and upstream of the first outlet and second outlet.
1. An ejector comprising:
a first inlet;
a second inlet;
an outlet;
a first flowpath from the first inlet to the outlet;
a second flowpath from the second inlet to the outlet; and
a first nozzle along the first flowpath, the first flowpath and second flowpath merging downstream of the first nozzle,
characterized by:
a second nozzle along the second flowpath, the first flowpath and second flowpath merging in a plenum downstream of the second nozzle and upstream of at least one diffuser;
the at least one diffuser comprises:
a first diffuser in a first mixer and diffuser unit along the first flowpath; and
a second diffuser in a second mixer and diffuser unit along the second flowpath;
the first nozzle and the second nozzle each having a central motive flow passageway; and
the ejector further comprising at least one actuator for selectively opening and closing a bypass of the central passageway of at least one of the first nozzle and the second nozzle.
8. An ejector comprising:
a first inlet;
a second inlet;
an outlet;
a first flowpath from the first inlet to the outlet;
a second flowpath from the second inlet to the outlet; and
a first nozzle along the first flowpath, the first flowpath and second flowpath merging downstream of the first nozzle,
characterized by:
a second nozzle along the second flowpath, the first flowpath and second flowpath merging in a plenum downstream of the second nozzle and upstream of a first diffuser and a second diffuser, wherein:
in a first mode, a first mode first flow through the first inlet is a motive flow passing through the first nozzle and a first mode second flow through the second inlet is a secondary flow merging with the motive flow in the plenum; and
in a second mode, a second mode second flow through the second inlet is a motive flow passing through the second nozzle and a second mode first flow through the first inlet is a secondary flow merging with the motive flow in the plenum.
11. A vapor compression system comprising:
a compressor;
a first heat exchanger;
a second heat exchanger;
a separator having:
an inlet;
a liquid outlet; and
a vapor outlet;
an expansion device;
an ejector comprising:
a first inlet;
a second inlet;
a first outlet;
a second outlet;
a first flowpath from the first inlet to the first outlet;
a second flowpath from the second inlet to the second outlet;
a first nozzle along the first flowpath;
a second nozzle along the second flowpath, the first flowpath and second flowpath merging downstream of the first nozzle and second nozzle and upstream of the first outlet and second outlet; and
a plurality of conduits and at least one valve positioned to define:
a first mode flowpath sequentially through:
the compressor;
the first heat exchanger;
the ejector from the first inlet through the ejector outlet; and
the separator, and then branching into:
a first mode first branch returning to the compressor; and
a first mode second branch passing through the expansion device and second heat exchanger to the second inlet; and
a second mode flowpath sequentially through:
the compressor;
the second heat exchanger;
the ejector from the second inlet through the ejector outlet; and
the separator, and then branching into:
a second mode first branch returning to the compressor; and
a second mode second branch passing through the expansion device and first heat exchanger to the first inlet.
13. A vapor compression system comprising:
a compressor;
a first heat exchanger;
a second heat exchanger; and
a separator having:
an inlet;
a liquid outlet; and
a vapor outlet;
an expansion device,
an ejector comprising:
a first inlet;
a second inlet;
an outlet;
a first flowpath from the first inlet to the outlet;
a second flowpath from the second inlet to the outlet;
a first nozzle along the first flowpath, the first flowpath and second flowpath merging downstream of the first nozzle;
a second nozzle along the second flowpath, the first flowpath and second flowpath merging in a plenum downstream of the second nozzle and upstream of at least one diffuser, the first nozzle and the second nozzle each having a central motive flow passageway; and
at least one actuator for selectively opening and closing a bypass of the central passageway of at least one of the first nozzle and the second nozzle;
a plurality of conduits and at least one valve positioned to define:
a first mode flowpath sequentially through:
the compressor;
the first heat exchanger;
the ejector from the first inlet through the ejector outlet; and
the separator, and then branching into:
a first mode first branch returning to the compressor; and
a first mode second branch passing through the expansion device and second heat exchanger to the second inlet; and
a second mode flowpath sequentially through:
the compressor;
the second heat exchanger;
the ejector from the second inlet through the ejector outlet; and
the separator, and then branching into:
a second mode first branch returning to the compressor; and
a second mode second branch passing through the expansion device and first heat exchanger to the first inlet.
2. The ejector of
the outlet comprises a first outlet and a second outlet;
the first flowpath is from the first inlet to the first outlet; and
the second flowpath is from the second inlet to the second outlet.
3. The ejector of
the at least one actuator comprises a first actuator coupled to the first nozzle and a second actuator coupled to the second nozzle.
5. The vapor compression system of
a compressor;
a first heat exchanger;
a second heat exchanger; and
a separator having:
an inlet;
a liquid outlet; and
a vapor outlet;
an expansion device.
6. The vapor compression system of
a first mode flowpath sequentially through:
the compressor;
the first heat exchanger;
the ejector from the first inlet through the ejector outlet; and
the separator, and then branching into:
a first mode first branch returning to the compressor; and
a first mode second branch passing through the expansion device and second heat exchanger to the second inlet; and
a second mode flowpath sequentially through:
the compressor;
the second heat exchanger;
the ejector from the second inlet through the ejector outlet; and
the separator, and then branching into:
a second mode first branch returning to the compressor; and
a second mode second branch passing through the expansion device and first heat exchanger to the first inlet.
7. The vapor compression system of
the first heat exchanger is a refrigerant-air heat exchanger; and
the second heat exchanger is a refrigerant-water heat exchanger.
10. The vapor compression system of
a first mode flowpath sequentially through:
the compressor;
the first heat exchanger;
the ejector from the first inlet through the ejector outlet; and
the separator, and then branching into:
a first mode first branch returning to the compressor; and
a first mode second branch passing through the expansion device and second heat exchanger to the second inlet; and
a second mode flowpath sequentially through:
the compressor;
the second heat exchanger;
the ejector from the second inlet through the ejector outlet; and
the separator, and then branching into:
a second mode first branch returning to the compressor; and
a second mode second branch passing through the expansion device and first heat exchanger to the first inlet.
12. The vapor compression system of
the first flowpath and second flowpath merge upstream of the first diffuser and second diffuser.
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This is a divisional application of PCT/US2016/037822, filed Jun. 16, 2016, and entitled “Ejector Heat Pump” and priority is claimed of Chinese Patent Application No. 201510383148.2, filed Jul. 3, 2015, the disclosures of which applications are incorporated by reference in their entireties herein as if set forth at length.
The present disclosure relates to refrigeration. More particularly, it relates to ejector refrigeration systems.
Earlier proposals for ejector refrigeration systems are found in U.S. Pat. Nos. 1,836,318 and 3,277,660. An ejector heat pump system is disclosed in CN204115293U.
From the separator, the flowpath branches into a first branch 61 completing the primary loop 60 to return to the compressor and a second branch 63 forming a portion of a secondary loop 62. The secondary loop 62 of the refrigerant circuit 27 includes a heat exchanger 64 (in a normal operational mode being a heat absorption heat exchanger (e.g., evaporator)). The evaporator 64 includes an inlet 66 and an outlet 68 along the secondary loop 62. An expansion device 70 is positioned in a line 72 which extends between the separator liquid outlet 52 and the evaporator inlet 66. An ejector secondary inlet line 74 extends from the evaporator outlet 68 to the ejector secondary flow inlet 42.
In the normal mode of operation, gaseous refrigerant is drawn by the compressor 22 through the suction line 56 and inlet 24 and compressed and discharged from the discharge port 26 into the discharge line 28. In the heat rejection heat exchanger, the refrigerant loses/rejects heat to a heat transfer fluid (e.g., fan-forced air or water or other fluid). Cooled refrigerant exits the heat rejection heat exchanger via the outlet 34 and enters the ejector primary flow inlet 40 via the line 36.
An exemplary implementation is a chiller wherein the evaporator 64 is a refrigerant-water heat exchanger having a refrigerant flowpath leg 80 in heat exchange relation with a water flowpath leg 82 carrying a flow of water 84 between an inlet 86 and an outlet 88. In the normal cooling mode, refrigerant along the leg 80 absorbs heat from water along the leg 82.
The exemplary ejector 38 (
Use of an ejector serves to recover pressure/work. Work recovered from the expansion process is used to compress the gaseous refrigerant prior to entering the compressor. Accordingly, the pressure ratio of the compressor (and thus the power consumption) may be reduced for a given desired evaporator pressure. The quality of refrigerant entering the evaporator may also be reduced. Thus, the refrigeration effect per unit mass flow may be increased (relative to the non-ejector system). The distribution of fluid entering the evaporator is improved (thereby improving evaporator performance). Because the evaporator does not directly feed the compressor, the evaporator is not required to produce superheated refrigerant outflow. The use of an ejector cycle may thus allow reduction or elimination of the superheated zone of the evaporator. This may allow the evaporator to operate in a two-phase state which provides a higher heat transfer performance (e.g., facilitating reduction in the evaporator size for a given capability).
The exemplary ejector may be a fixed geometry ejector or may be a controllable ejector.
One aspect of the disclosure involves a vapor compression system comprising a plurality of valves controllable to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: a compressor; a first heat exchanger; a first nozzle; and a separator, and then branching into: a first branch returning to the compressor; and a second branch passing through an expansion device and a second heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator. The second mode flowpath is sequentially through: the compressor; the second heat exchanger; a second nozzle; and the separator, and then branching into: a first branch returning to the compressor; and a second branch passing through the expansion device and first heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator.
Another aspect of the disclosure involves a vapor compression system comprising: a compressor; a first heat exchanger; a second heat exchanger; and a separator having: an inlet; a liquid outlet; and a vapor outlet; an expansion device; and a plurality of conduits. The system further comprises a plurality of valves controllable to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: the compressor; the first heat exchanger; a first nozzle; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and second heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator. The second mode flowpath is sequentially through: the compressor; the second heat exchanger; a second nozzle; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and first heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator.
In one or more embodiments of any of the foregoing embodiments, the first nozzle is a motive nozzle of a first ejector and the second nozzle is a motive nozzle of a second ejector.
In one or more embodiments of any of the foregoing embodiments, one or more check valves are positioned to block reverse flow through at least one of the first ejector and second ejector.
Another aspect of the disclosure involves a vapor compression system having: a compressor; a first heat exchanger; a second heat exchanger; a first ejector; a separator; an expansion device; and a plurality of conduits. The first ejector comprises: a motive flow inlet; a secondary flow inlet; and an outlet. The separator has: an inlet; a liquid outlet; and a vapor outlet. The system further includes a second ejector comprising: a motive flow inlet; a secondary flow inlet; and an outlet. The system further includes a plurality of valves controllable to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: the compressor; the first heat exchanger; the first ejector from the first ejector motive flow inlet through the first ejector outlet; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and second heat exchanger to the first ejector secondary flow inlet. The second mode flowpath is sequentially through: the compressor; the second heat exchanger; the second ejector from the second ejector motive flow inlet through the second ejector outlet; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and first heat exchanger to the second ejector secondary flow inlet.
Another aspect of the disclosure involves a vapor compression system comprising: a compressor; a first heat exchanger; a second heat exchanger; at least one ejector; a separator having: an inlet; a liquid outlet; and a vapor outlet; an expansion device; and a plurality of conduits. The system further comprises a plurality of valves controllable to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: the compressor; the first heat exchanger; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and second heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator. The second mode flowpath is sequentially through: the compressor; the second heat exchanger in the same direction to flow in the first mode; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and first heat exchanger in the same direction to flow in the first mode to the rejoin the flowpath between the first heat exchanger and the separator.
In one or more embodiments of any of the foregoing embodiments, the plurality of valves comprises a valve positioned to selectively allow flow to the first ejector secondary flow inlet and the second ejector secondary flow inlet.
In one or more embodiments of any of the foregoing embodiments, the valve is configured allow flow to at most one of the first ejector secondary flow inlet and the second ejector secondary flow inlet.
In one or more embodiments of any of the foregoing embodiments, the first ejector and the second ejector are of different sizes.
In one or more embodiments of any of the foregoing embodiments, the first ejector has a greater throat cross-sectional than the second ejector.
In one or more embodiments of any of the foregoing embodiments, the first ejector has a greater mixer cross-sectional area than the second ejector.
In one or more embodiments of any of the foregoing embodiments, the first heat exchanger is a refrigerant-air heat exchanger and the second heat exchanger is a refrigerant-water heat exchanger.
In one or more embodiments of any of the foregoing embodiments, the plurality of valves comprises a first four way valve and a second four way valve.
Another aspect of the disclosure involves a method for operating a vapor compression system comprising: a compressor; a first heat exchanger; a second heat exchanger; at least one ejector; a separator having: an inlet; a liquid outlet; and a vapor outlet; and an expansion device. The method comprises, in a first mode, compressing refrigerant with the compressor to drive the refrigerant along a first mode flowpath sequentially through: the compressor; the first heat exchanger; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and second heat exchanger to the rejoin the flowpath between the first heat exchanger and the separator. The method further comprises, in a second mode, compressing refrigerant with the compressor to drive the refrigerant along a second mode flowpath sequentially through: the compressor; the second heat exchanger in the same direction to flow in the first mode; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and first heat exchanger in the same direction to flow in the first mode to the rejoin the flowpath between the first heat exchanger and the separator.
In one or more embodiments of any of the foregoing embodiments, aspects may be as described herein for the systems.
Another aspect of the disclosure involves an ejector comprising: a first inlet; a second inlet; an outlet; a first flowpath from the first inlet to the outlet; a second flowpath from the second inlet to the outlet; and a first nozzle along the first flowpath. The first flowpath and second flowpath merge downstream of the first nozzle. A second nozzle is along the second flowpath, the first flowpath and second flowpath merging downstream of the second nozzle.
In one or more embodiments of any of the foregoing embodiments, the outlet comprises a first outlet and a second outlet; the first flowpath is from the first inlet to the first outlet; and the second flowpath is from the second inlet to the second outlet.
In one or more embodiments of any of the foregoing embodiments, the first flowpath and second flowpath merge in a plenum.
In one or more embodiments of any of the foregoing embodiments, the ejector further comprises a first mixer and diffuser unit along the first flowpath and a second mixer and diffuser unit along the second flowpath.
In one or more embodiments of any of the foregoing embodiments, the first nozzle and the second nozzle each have a central motive flow passageway and the ejector further comprises at least one actuator for selectively opening and closing a bypass of the central passageway of the first nozzle and the second nozzle.
In one or more embodiments of any of the foregoing embodiments, the actuator comprises a first actuator coupled to the first nozzle and a second actuator coupled to the second nozzle.
In one or more embodiments of any of the foregoing embodiments, a vapor compression system comprises the ejector.
In one or more embodiments of any of the foregoing embodiments, the vapor compression system further comprises: a compressor; a first heat exchanger; a second heat exchanger; and a separator having: an inlet; a liquid outlet; and a vapor outlet; an expansion device.
In one or more embodiments of any of the foregoing embodiments, the vapor compression system further comprises a plurality of conduits and at least one valve positioned to define a first mode flowpath and a second mode flowpath. The first mode flowpath is sequentially through: the compressor; the first heat exchanger; the ejector from the first inlet through the ejector outlet; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and second heat exchanger to the second inlet. The second mode flowpath is sequentially through: the compressor; the second heat exchanger; the ejector from the second inlet through the ejector outlet; and the separator, and then branching into a first branch returning to the compressor and a second branch passing through the expansion device and first heat exchanger to the first inlet.
In one or more embodiments of any of the foregoing embodiments, the first heat exchanger is a refrigerant-air heat exchanger; and the second heat exchanger is a refrigerant-water heat exchanger.
In one or more embodiments of any of the foregoing embodiments, a method for using the ejector comprises: in a first mode, passing a first flow to the first inlet and a second flow to the second inlet, the second flow having a lower pressure at the second inlet than the first flow at the first inlet; and in a second mode, passing a first flow to the first inlet and a second flow to the second inlet, the second flow having a greater pressure at the second inlet than the first flow at the first inlet.
In one or more embodiments of any of the foregoing embodiments: in the first mode, the first flow is a motive flow and the second flow is a secondary flow; and in the second mode, the first flow is a secondary flow and the second flow is a motive flow.
The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.
Like reference numbers and designations in the various drawings indicate like elements.
To provide for switching between these two modes (and any additional modes) relative to the baseline system of
Additionally, the single ejector of
The exemplary added valves (260, 262, 264) include a four-way valve 260 linking the compressor discharge line/conduit with a conduit/line of the cooling mode secondary loop between the expansion device 70 and the heat exchanger 64. The exemplary valve 262 is also a four-way valve linking the line/conduit of the cooling mode primary loop between the heat exchanger 30 and ejectors on the one hand and a line/conduit of the secondary loop between the heat exchanger 64 and the ejector 220 secondary flow inlet 224 on the other hand.
A third valve 264 is a three-way valve selectively providing communication between the valve 262 on the one hand and either the first ejector secondary flow inlet or the second ejector secondary flow inlet.
The exemplary valves 260 and 262 are illustrated as rotary element valves having a rotary element (e.g., rotated manually or via an electric actuator) having a plurality of passageways which selectively register with associated ports in a housing. The exemplary valves 260 and 262 have two sets of passageways: a first set which registers with the housing ports in the cooling mode and a second set which registers with the housing ports in the heating mode. Alternative valves might involve using the same passageways for both modes but with a different orientation. Yet alternative valves include other configurations such as spool valves and the like.
The three-way valve 264 may also be a simple rotary valve, spool valve, or the like. Due to the simple switching function of this valve, its passageways in its valve element are not shown.
Operation in the cooling mode is as described for
Subject to the action of the valve 264, the two ejectors are effectively physically in parallel with their primary unit inlets 222, 242 in communication with the valve 262 and their outlets in communication with the separator inlet 50. This allows, via use of the valve 264, either of the ejectors to operate and discharge into the separator 48 so that the same separator 48 is used with both ejectors and the system has only a single separator.
In the
Thus, it is seen that the valve 260 addresses switching of the roles of the heat exchangers 30 and 64 at their inlet ends. Similarly, the valve 262 addresses the role reversal at outlet ends of the heat exchangers in that it passes outlet flows from the heat exchangers. In the
In the
The two ejectors may have one or more of several asymmetries relative to each other to tailor the ejectors for the particular anticipated conditions of respective cooling mode and heating mode operation. For example, one highly likely difference is the throat area. Specifically, first ejector 220 (the ejector used in the normal cooling mode) may have one or more different size and/or capacity parameters than the second ejector 240(the ejector used in the normal heating mode). The nature and direction of asymmetry may depend on design conditions (e.g., a system designed for warm summers and warm winters may have a difference relative to one designed for cool summers and cool winters).
For example throat cross-sectional area of one ejector may be greater than that of the other ejector (e.g., at least 5% greater or at least 10% or at least 20% or at least 30% or at least 50%, with exemplary upper ends on ranges being 100% greater or 80% greater or 60% greater). Another possible difference is mixer cross-sectional area. This area may differ by the same amounts as those listed for throat area.
The
As is discussed further below the exemplary ejector assembly 602 has at least two modes of operation. In one or more first modes, the inlet 604 is a motive or primary flow inlet and the inlet 606 is a suction or secondary flow inlet. In one or more second modes, the functions are reversed so that the inlet 604 is the suction or secondary flow inlet and the inlet 606 is the motive or primary flow inlet.
Otherwise similar to the
The exemplary ports 604, 606 are coupled to respective nozzle units 620, 622. The exemplary nozzle units are nozzle/needle units having a nozzle 624, 625 and a needle 626, 627. The nozzle may be configured as the motive nozzle discussed above having similar features which are not separately discussed.
Each unit 620, 622 comprises a body 640 holding the motive nozzle 624, 625.
The opening of the flow along the path 660 may be accompanied by a closing of flow along the central passageway of the subject motive nozzle (e.g., via a sealing engagement of the needle with the throat).
Exemplary motive nozzle actuation may be via solenoid, stepper motor, or the like. An exemplary actuator 670 may have a fixed portion 672 (e.g., solenoid coil unit) and a moving portion 674 (e.g., solenoid plunger). The moving portion may be coupled to the associated motive nozzle by a linkage 676 (e.g., a circumferential array of arms having first ends mounted at a downstream end of the plunger and second ends mounted to the flange to define a cage). The cross-sectional area along the flowpath 660 is substantially greater than the minimum cross-sectional area along the flowpath through the motive nozzle (e.g., the throat area). This can allow the open flow passage 660 of one of the units 620, 622 to carry a suction/secondary flow driven by a motive flow passed through the central passageway of the other of the units 620, 622. To do this, the two units 620, 622 feed a plenum 680 having respective inlets receiving flows from the units 620, 622 and outlet ports positioned to feed the mixer(s) and diffuser(s). In the exemplary implementation, each mixer/diffuser unit is approximately aligned with its associated nozzle unit 620, 622. When a given nozzle unit is utilized to pass motive flow, the associated mixer/diffuser 650, 652 may be open (e.g., via its valve 616, 618) while the other mixer/diffuser unit is closed.
The crossing orientation of the nozzle units and mixer/diffuser units may facilitate flow mixing (e.g., as opposed to having a parallel orientation). Based upon anticipated flow conditions, the angles may be optimized considering the complicated momentum mixing during the supersonic two phase flow process. Exemplary angles between axes of the two nozzle units may be between 0° and 90° or 30° and 90° or 40° and 70°. Similarly, exemplary angles between axes of the two mixer/diffuser units may be between 0° and 90° or 30° and 90° or 40° and 70°.
Switching between the heating mode and cooling mode may involve a similar actuation of valves 260 and 262 as is used in either of the other embodiments. The valve 264 is eliminated or avoided.
In the exemplary system 600, switching between the heating mode and cooling mode involves the actuation of the nozzle actuators 670 of the two units, the needle actuators 630 of the two units, and the four-way valve 260. For example, in the cooling mode, the flow passage through the four-way valve 260 is shown in
In the exemplary system 600, the motive nozzle units and the mixer/diffuser units may have similar asymmetries to those of the ejectors of the
Either or both ejectors may be used in each of the cooling and heating modes. The particular ejector or combination of ejectors used in a given mode may be selected to best correspond to the requirements of such mode.
In contrast to
The systems may be made using otherwise conventional or yet-developed materials and techniques.
The use of “first”, “second”, and the like in the description and following claims is for differentiation within the claim only and does not necessarily indicate relative or absolute importance or temporal order. Similarly, the identification in a claim of one element as “first” (or the like) does not preclude such “first” element from identifying an element that is referred to as “second” (or the like) in another claim or in the description.
One or more embodiments have been described. Nevertheless, it will be understood that various modifications may be made. For example, when applied to an existing basic system, details of such configuration or its associated use may influence details of particular implementations. Accordingly, other embodiments are within the scope of the following claims.
Radcliff, Thomas D., Verma, Parmesh, Liu, Hongsheng
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